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A native ant armed to limit the spread of the Argentine ant

A native ant armed to limit the spread of the Argentine ant
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  ORIGINAL PAPER A native ant armed to limit the spread of the Argentine ant Olivier Blight  • Erick Provost  • Marielle Renucci  • Alain Tirard  • Je´ro ˆme Orgeas Received: 8 December 2009/Accepted: 26 April 2010/Published online: 9 May 2010   Springer Science+Business Media B.V. 2010 Abstract  Argentine ants (  Linepithema humile ) usu-ally actively displace native ants through a combina-tion of rapid recruitment, high numerical dominanceand intense aggressive fights.However, in some cases,native ants can offer a strong resistance. In Corsica, aFrench Mediterranean island, local resistance by thedominant  Tapinoma nigerrimum  has been proposed asa factor limiting Argentine ant invasion. With the aimof evaluating the abilities of   T. nigerrimum  ininterference and exploitative competition, this studytested in the laboratory the aggressive interactionsbetween this native dominant ant and the invasiveArgentine ant. We used four different assays between  L. humile  and  T. nigerrimum : (1) worker dyadicinteractions, (2) symmetrical group interactions, (3)intruder introductions into an established residentcolony, and (4) a competition for space and food. Thisstudy confirms the ability of Argentine ants tocompete with native species, by initiating more fights,using cooperation and simultaneously deployingphysical and chemical defenses. However, despiteArgentine ant fighting capabilities,  T. nigerrimum  wasmore efficient in both interference and exploitativecompetition. Its superiority was obvious in the spaceand food competition assays, where  T. nigerrimum dominated food in 100% of the replicates after 1 h andinvaded Argentine ant nests while the reverse wasnever observed. The death feigning behavior exhib-ited by Argentine ant workers also suggests the nativeant’s superiority. Our study thus demonstrates that T. nigerrimum  can offer strong competition and somay be able to limit the spread of Argentine ants inCorsica. This confirms that interspecific competitionfrom ecologically dominant native species can affectthe invasion success of invaders, notably by decreas-ing the likelihood of incipient colony establishmentand survival. Keywords  L. humile    T. nigerrimum   Competition    Bioassays    Propagule   Invasion process Introduction The introduction of exotic species to a previouslyunoccupied region is considered to be a key threat tothe integrity of many natural habitats and ecosystemsworldwide (Vitousek et al. 1997). Among invasivearthropod species, ants are considered as seriousecological and economic pests (Holway et al. 2002a).These invasions are multi-step processes and occurwhen species are transported and become established O. Blight ( & )    E. Provost    M. Renucci   A. Tirard    J. OrgeasInstitut Me´diterrane´en d’Ecologie et de Pale´oe´cologie(UMR CNRS/IRD), Universite´ Paul Ce´zanne, EuropoˆleMe´diterrane´en de l’Arbois BP 80, 13545 Aix-en-Provencecedex 4, Francee-mail:  1 3 Biol Invasions (2010) 12:3785–3793DOI 10.1007/s10530-010-9770-3  in a new range in which they persist, proliferate andspread (Kolar and Lodge 2001; Mack et al. 2002). The earliest stage of the invasion process after arrival,i.e. the dynamics of establishment and initial persis-tence of an incipient colony, is a critical stage in thesuccess of invasive ants. The differences in successnot only among genera but also for one species indifferent field contexts suggest that several factorssuch as propagule pressure (Lockwood et al. 2005),specific ecological characteristics (e.g. nesting habits,Suarez et al. 2005), abiotic conditions (Holway 1998; Holway et al. 2002b; Thomas and Holway 2005) and competition from ecologically dominant or function-ally similar species (Walters and Mackay 2005) mayinfluence species establishment and survival. As soonas exotic ants arrive in new habitats, they compete forresources (food and space) with native ants. Theirability to survive long enough and to displace enoughnative colonies is critical to their becoming domi-nant and invasive. Sometimes they succeed (Humanand Gordon 1996), sometimes they fail (Walters andMackay 2005).Like many invasive ant species,  Linepithemahumile  (  Dolichoderinae ) spreads easily around theworld from its native range in South America, mainlythrough trade (Suarez et al. 2001). Argentine antsgenerally prosper in disturbed or modified habitatssuch as agricultural land and urban environments.They are one of the most damaging invaders both inecological and in economic terms (Vega and Rust2001). They invariably reduce the number of nativeant species (Rowles and O’Dowd 2007; Suarez et al.1998). They can also negatively affect other non-antinvertebrates (Cole et al. 1992; Human and Gordon1997) and can disrupt important ant-plant mutualisticrelationships (Carney et al. 2003; Christian 2001; Gomez and Oliveras 2003).  L. humile  displayscharacteristics typical of tramp species, such as smallsize, monomorphism of worker caste, high polygyny,reproduction by budding and unicoloniality (Ho¨lldo-bler 1990; Passera 1994). Argentine ants are strong competitors in both forms of competition occurringin ant communities, i.e. exploitative competition andinterference competition (Holway 1999; Human andGordon 1996; Rowles and O’Dowd 2007). Exploit- ative competition involves the ability of an antspecies to locate a resource quickly and recruit largenumbers of workers to the resource before otherspecies of ants arrive (Ho¨lldobler 1990). Interferencecompetition involves the ability of an ant species todefend a resource from other ant species or dominatea resource by aggressively displacing the ants alreadyat the resource (Ho¨lldobler 1990). Within the intro-duced range,  L. humile  exhibits unicolonial colonystructures consisting of large colonies that lack boundaries due to absence of aggression (Blightet al. 2010; Giraud et al. 2002; Tsutsui et al. 2000). They compensate for their mortality rate with highworker numbers, forage more efficiently and mayallocate more resources to colony growth, providingthis invader with a numerical advantage allowingrapid recruitment of many workers and thus makingthem strong competitors for resources exploitation(Holway 1999; Human and Gordon 1996, 1999). Among the contributing factors which may explainthe interference competitive asymmetry betweenArgentine ants and native ants, numerical superiority(Holway 1999; Human and Gordon 1999), aggres- siveness (Carpintero and Reyes-Lopez 2008; Holwayand Case 2001; Human and Gordon 1999) and fight strategies such as cooperation or defensive tech-niques are thought to be the most important (Bucz-kowski and Bennett 2008; Holway 1999). For instance, their ability to use simultaneously mechan-ical and chemical defenses influences the outcome of fights against  Tapinoma sessile  (Buczkowski andBennett 2008).Native ants are affected by  L. humile  to varyingdegrees due to different intensities of competitiveand aggressive interactions (Carpintero et al. 2007;Human and Gordon 1996). For instance, Holway(1999) observed that Argentine ants reduced thenumbers of several native ant workers, with thenotable exception of   Monomorium ergatogyna . Insome cases, local ants can offer strong resistance andcan delay or prevent the spread of Argentine ants(Walters and Mackay 2005; Way et al. 1997; Wetterer et al. 2006). This strong competition usually occurswhen the invader encounters an ecologically domi-nant or functionally similar native species. In Corsica,a French Mediterranean island, two ant species fromthe genus  Tapinoma ,  Tapinoma nigerrimum  and Tapinoma simrothi , can be described as dominant inthe sense that they are widespread and abundantforming large polygynous and polydomous colonieswith interconnected nests with thousands of workersand displaying mass recruitment to a food source(personal observation). They belong to the subfamily 3786 O. Blight et al.  1 3   Dolichoderinae  and have polymorphic workers rang-ing from 2.5 to 5.1 mm (Gomez and Espadaler 1998).They share numerous features of foraging with theArgentine ant (e.g. mass recruitment and similardiet, with a preference for hemipterans exudates). T. nigerrimum  was considered as dominant whencompeting for food with  L. humile  in Portuguese openland (Way et al. 1997). Given the morphological,behavioral, and ecological characteristics of the two Tapinoma  species, local resistance has been proposedto explain Argentine ant distribution in Corsica(Blight et al. 2009; Casevitz-Weulersse and Brun1999). While  L. humile  and the two  Tapinoma  speciesusually share the same habitat, and are present alongthe Corsican coast, only two co-occurrences havebeen observed between small colonies of both species.An almost systematic exclusion seemed to arisebetween Argentine ants and  Tapinoma . Despite amarked spread over the last decade, Argentine antsare found discontinuously along the coastal strip(Blight et al. 2009). This observation is interestingconsidering the relative fragility of island populations(Williamson 1996) and the invasiveness of theArgentine ant notably in Mediterranean Island eco-systems (Gomez and Espadaler 2006).With the aim of evaluating the performance of Corsican  Tapinoma  in both interference and exploit-ative competition, this laboratory study testedaggressive interactions with the invasive Argentineant. Due to the close biological, behavioral, mor-phological and ecological similarities between thetwo  Tapinoma  species present on the island, weperformed our experiments using  T. nigerrimum  themost common species along the Corsican coast. Weconducted four different assays: (1) worker-dyadinteractions and (2) symmetrical group interactionsto test species’ capacity for interference competition,(3) intruder introductions into an established residentcolony to test the defense capabilities of wholecolonies against individual workers and vice versaand (4) a resource competition assay focusing oncompetition for food and nesting space to helpexplain species’ capacity for exploitative competi-tion. These bioassays were conducted to answer thefollowing questions: is  T. nigerrimum  armed andable (1) to compete with the Argentine ant and (2) tolimit the success of this invader establishment,survival and spread? Materials and methods Study context and field collectionArgentine ants and  T. nigerrimum  colony fragmentswere both collected in the north of Corsica in June2008. A minimum of 10,000 workers and 20 queenswere collected from one nest of each colony. Nestfragments were kept in a plastic nest container (360  9 240  9  110 mm) filled with srcinal nest material. Inaddition to proteins provided by arthropods caughtwith their srcinal substrate, ants were fed with honey.Colonies were maintained in the laboratory at23  ±  2  C with the appropriate soil moisture.Behavioral assaysFor the purposes of comparison with the findings of Buczkowski and Bennett (2008), who studied inter-actions between the Argentine ant and the odoroushouse ant,  Tapinoma sessile , we performed behav-ioral assays analogous to theirs. One-on-one The one-on-one bioassays were conducted in plasticdishes of 5.5 cm of diameter, with the aim of determining the fighting abilities of individual work-ers of both species. Behavioral tests were videotapedfor 15 min and saved on a storage unit. From therecording videotape, we monitored behavioral inter-actions between workers, using the following classi-fication of ant interactions: 1  =  ignore, 2  =  avoid,3  =  aggression (lunging, brief bouts of biting, and/orpulling), 4  =  fighting (prolonged aggression, alsoabdomen curling to deposit defensive compounds)(Suarez et al. 2002). We conserved the maximumscore per trial, averaged across forty replicates. Wealso recorded the fight initiator, the fight winner (aspecies was considered as winner when it killed theother species) and the techniques employed by bothspecies (i.e. physical aggression, chemical defenses,or both). Physical aggressions were defined ascommencing as soon as workers opened their man-dibles to bite the enemy and the use of chemicaldefenses (toxic venom) was defined as when weobserved gaster flexions. A native ant armed to limit the spread of the Argentine ant 3787  1 3  Symmetrical group confrontation The objective of this symmetrical group confronta-tion assay was to test the competitive ability of thetwo species in equal groups. Twenty-five randomlyselected workers of both species were transferredsimultaneously to a plastic dish (9 cm diameter) withmoist plaster. We monitored behavioral interactionsbetween workers during a 10 s scan every 2 min for20 min and then another 10 s scan at 40 min, 1, 2, 3,4 and 5 h after the bioassay began, using the previousant interaction classification. We conserved themaximum score per trial, averaged across sixteenreplicates. At each time point we also recorded thenumber of dead workers.  Intruder introduction An individual was introduced into a resident colonyof the other species. This experimental design wasused to simulate introduction  in natura  of individualsinto the enemy territory and to highlight differencesin the reaction of resident colonies of a native speciesand an invasive species toward enemy introductions.The intruder was removed from the colony 5 minafter the first contact with the workers of the residentcolony. We noted: the maximum level of aggression,the fight initiator and the number of resident colonyworkers involved in the fight. Forty introductions of Argentine ants into a resident colony of   T. nigerri-mum  and forty introductions of   T. nigerrimum  into aresident colony of Argentine ants were performed. Competition for space and food  500 workers, queens and brood from each of the twospecies were placed in closed artificial nests withmoist plaster (250  9  215  9  40 mm). Artificial nestswere connected via plastic tubes to a commonforaging arena (360  9  240  9  140 mm). Ants wereacclimated to their nests for 2 days without food. Onday 3, artificial nests were opened, allowing theworkers to access the foraging arena where honeywas placed in the center. After the nests were opened,we monitored the colonies every hour over 8 hthe first day and then twice a day (morning andafternoon) for 5 days to determine which speciesdiscovered the food first, which species dominatedthe food resource over the 6 days of interactions andwhere both species nested. At the end of the test(day 8), we recorded the distribution of workers of both species, noting whether the ants nested in theirown nest and/or the nest of the opposing species andrecording the number of dead ants. Eight replicates of this resource competition test were conducted. Statistical analyses Prior to statistical analysis, we examined all datadistributions using the Shapiro–Wilk W test fornormality. Except for differences in number of deadworkers at the end of the group confrontation, datadid not conform to a normal distribution even afterlog transformation. Differences in mortality at theend of the group confrontation were analyzed using aStudent  t  -test. Differences in levels of aggressiveinteractions and in number of ants involved in fightswere compared using the non-parametric Mann–Whitney  U   test for independent data. Differences inmortality in the competition for space and foodbioassay were compared using the non-parametricWilcoxon signed-rank test for dependent data. Dif-ferences in the proportion of fight winner, fightinitiator and defensive techniques employed in fightswere analyzed using Fisher’s exact test and Chi-square test. All data analyzes were performed usingthe software Statistica v.6 (Statsoft 2001). Results One-on-oneOne-on-one bioassay showed moderate aggression.The maximum aggression score was on average3.3  ±  0.1 SE between  L. humile  and  T. nigerrimum .Actsofaggressionchieflyconsistedofbriefaggressivecontacts. We counted 253 aggressive interactionsamong the 40 replicates. An average of seven interac-tions was recorded per replicate.  T. nigerrimum initiated 103/253 (41%) whereas Argentine ants initi-ated 150/253 (59%) ( df   =  1,  P \ 0.0001, Chi-squaretest) (Table 1).Although  T. nigerrimum  initiated less aggressiveinteractions, they won (death of the Argentine antworker) 7/40 (17.5%) of the replicates and Argentineants won (death of the  T. nigerrimum  worker) only1/40 (2.5%) of the replicates ( df   =  1,  P \ 0.05, 3788 O. Blight et al.  1 3  Fisher’s exact test) (Table 1). In 31/40 (77.5%) nowinner was identified at the end of the 15 min andone encounter led to the death of both species.Both species used physical aggression and chem-ical defensive compounds in fights. Argentine antworkers used chemical defense (either alone or inconjunction with physical defenses) in 30/40 (75%)replicates and they used physical aggression (eitheralone or in conjunction with chemical defenses) in 22/ 40 (55%) ( df   =  1,  P  =  0.05, Fisher’s exact test)(Fig. 1a).  T. nigerrimum  used chemical defense(either alone or in conjunction with physical defenses)in 10/40 (25%) and they used physical aggression(either alone or in conjunction with chemicaldefenses) in 23/40 (57.5%) of the replicates (Fig. 1a)( df   =  1,  P \ 0.01, Fisher’s exact test) (Fig. 1a).Argentine ants used both types of aggressionsimultaneously in 19/40 (47.5%) of the replicateswhereas  T. nigerrimum  used both types of aggressionin only 9/40 (22.5%) of the replicates ( df   =  1, P \ 0.05, Fisher’s exact test) (Fig. 1b).  L. humile used only physical aggression in 3/40 (7.5%) of theinteractions and  T. nigerrimum  used only physicalaggression in 14/40 (35%) of the interactions ( df   =  1, P \ 0.01, Fisher’s exact test). Both species also usedonly chemical aggression, Argentine ants in 11/40(27.5%) of the interactions and  T. nigerrimum  in1/40 (2.5%) of the interactions between the twospecies ( df   =  1,  P \ 0.01, Fisher’s exact test)(Fig. 1b). Finally, Argentine ant and  T. nigerrimum workers used no aggressive defenses respectively in7/40 (17.5%) and 16/40 (40%) of the replicates( df   =  1,  P \ 0.05, Fisher’s exact test).Symmetrical group confrontationAlthough these confrontations started with an equalnumber of 25 individuals, the fights became asymmet-rical,  T. nigerrimum  gaining an advantage overArgentine ant workers (Fig. 2). At the end of the test,differences in the mean number of dead workers werenearlysignificant,withanaverageof16  ±  1SE(64%)Argentine ants and 13  ±  1 SE (52%)  T. nigerrimum dead workers ( n  =  16) ( t   = - 1.92,  df   =  15,  P  = 0.07).The maximum aggression score was on average 4,the maximum level which corresponded to long Table 1  Frequency of fight initiations and fight winner in theone-on-one bioassay, fight initiator ( n  =  253), fight winner( n  =  40)Fight initiator Fight winner T. nigerrimum  103/253 (41%) 7/40 (17.5%)  L. humile  150/253 (59%) 1/40 (2.5%) 020406080100 e l i m u h a m e h t i p e n i Lm u m i r r e g i n a m o n i p a T     F  r  e  q  u  e  n  c  y  o   f   t  e  c   h  n   i  q  u  e  s  e  m  p   l  o  y  e   d   i  n   f   i  g   h   t  s physicalchemical a * ns physical only chemical only both none020406080100    F  r  e  q  u  e  n  c  y  o   f   t  e  c   h  n   i  q  u  e  s  e  m  p   l  o  y  e   d   i  n   f   i  g   h   t  s b L. humile T. nigerrimum  **** Fig. 1  The frequency of use  a  of physical and chemicaldefenses in the Argentine ant and  T. nigerrimum  and  b  of physical defense alone, chemical defense alone, physical andchemical defense simultaneously and lack of any defensivetechniques ( n  =  40), ns indicates non significant, * \ 0.05 2 4 6 8 10 12 14 16 18 20 40 60 120 180 240 300    A  v  e  r  a  g  e  c  u  m  u   l  a   t   i  v  e  n  u  m   b  e  r  o   f   d  e  a   d  w  o  r   k  e  r  s   (  ±   S   E   ) Time (min) L. humile T. nigerrimum  024681012141618 Fig. 2  Average cumulative number of dead ( ± SE) of Argen-tine ant and  T. nigerrimum  workers in symmetrical groupconfrontations ( n  =  16)A native ant armed to limit the spread of the Argentine ant 3789  1 3
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